An electronic component manufacturing method for obtaining an electronic component in which a resin molded body and an object are integrally formed and the resultant device is provided. The method includes forming a resin distribution set by feeding a resin material in granular, powder, or liquid form onto a release film in a resin receiving portion to create a non-uniform distribution, wherein the resin material is thicker at a predetermined location than at other locations. The resin distribution set including the release film and placing the resin distribution set onto a lower mold such are lifted and placed over a cavity in a lower mold. The release film covers an inner surface of the cavity, positioning the resin material in the cavity. The resin material is compression-molded with the object in contact with the resin material located in the cavity to obtain the device.

Apparatus for processing a wafer-shaped article, the apparatus comprising a support configured to support the wafer-shaped article during a processing operation; wherein: the support comprises a support body and a plurality of gripping pin assemblies adapted and positioned relative to the support body for gripping the wafer-shaped article, wherein each of the gripping pin assemblies is rotatable relative to the support body between a gripping configuration in which the gripping pin assemblies grip the wafer-shaped article, and a non-gripping configuration in which the gripping pin assemblies do not grip the wafer-shaped article; each of the gripping pin assemblies protrudes from a respective hole in the support body; and a sealing member is positioned between at least one of the gripping pin assemblies and the respective hole, the sealing member being configured to restrict infiltration of a processing liquid used in the processing operation into the hole.

The invention provides a semiconductor processing machine, which comprises a plurality of chambers, at least one of the chamber is a load-lock chamber, and the load-lock chamber comprises a bottom surface and a top lid opposite to the bottom surface; and a gas pipeline is connected with the top lid of the load-lock chamber.

A method of manufacturing a semiconductor package includes disposing a substrate strip having a plurality of semiconductor chips in a bottom mold, the bottom mold including sets of injection holes arranged on one side of the substrate strip, coupling the bottom mold and a top mold to contact each other, the top mold including cavities open toward corresponding ones of the sets of injection holes, individually injecting a first molding material and a second molding material into each of the cavities through injection holes included in a corresponding one of the sets of injection holes, respectively, forming a molding compound including the first molding material and the second molding material in the cavities, separating the top mold and the bottom mold from each other, curing the molding compound covering the semiconductor chips to form a mold structure, and cutting the mold structure.

Exemplary substrate processing systems may include a chamber body defining a transfer region. The systems may include a lid plate seated on the chamber body. The lid plate may define a first plurality of apertures and a second plurality of apertures. The systems may include a plurality of lid stacks equal to a number of the first plurality of apertures. Each lid stack may include a choke plate seated on the lid plate along a first surface of the choke plate. The choke plate may define a first aperture axially aligned with an associated aperture of the first plurality of apertures. The choke plate may define a second aperture axially aligned with an associated aperture of the second plurality of apertures. The choke plate may define protrusions extending from each of a top and bottom surface of the choke plate that are arranged substantially symmetrically about the first aperture.

Embodiments of the present disclosure herein include an apparatus for processing a substrate. More specifically, embodiments of this disclosure provide a substrate support assembly that includes an electrostatic chuck (ESC) assembly. The ESC assembly comprises a cooling base having a top surface and an outer diameter sidewall, an ESC having a substrate support surface, a bottom surface and an outer diameter sidewall, the bottom surface of the ESC coupled to the top surface of the cooling base by an adhesive layer. The substrate support assembly includes a blocking ring disposed around the outer diameter sidewalls of the cooling base and ESC, the blocking ring shielding an interface between the bottom surface of the ESC and the top surface of the cooling base.

A load port control unit performs an opening operation of a sealable container according to a first operation procedure when a sensor has detected a normal placement of the sealable container, and retries the opening operation according to a second operation procedure for being able to more reliably perform the opening operation of the sealable container, to prevent a transfer device from stopping, when the sensor has detected a placement abnormality of the sealable container.

A method of forming a semiconductor device includes mounting a bottom wafer on a bottom chuck and mounting a top wafer on a top chuck, wherein one of the bottom chuck and the top chuck has a gasket. The top chuck is moved towards the bottom chuck. The gasket forms a sealed region between the bottom chuck and the top chuck around the top wafer and the bottom wafer. An ambient pressure in the sealed region is adjusted. The top wafer is bonded to the bottom wafer.

An apparatus for inserting a seal member into a seal groove includes a tray. The tray includes a holding groove formed in a front surface for containing the seal member. The holding groove is sized and shaped to correspond with the seal groove. A method of installing a seal member into a seal groove includes aligning the holding groove with the seal groove, and applying a pressure to a back surface of the tray, thereby deforming the tray and inserting the seal member into the seal groove.

An apparatus for transferring light-emitting diodes (LEDs) includes a backing board for supporting a backplane, a sealing member formed on the backing board around a periphery of the backplane, a transparent panel formed on the sealing member such that a space is formed between the backing board and the transparent panel, and a vacuum source for drawing a vacuum on the space.